Access parameter adaptation and packet data resource management using detailed mobile status information

ABSTRACT

A wireless communication system wherein wireless infrastructure adapts access parameters and manages channel resources based on detailed reconnection information obtained from individual mobile stations. Mobile stations transmit particular reconnection attempt status information to the wireless infrastructure. The reconnection attempt status information, along with the aggregate statistics of other mobile stations, is used by the infrastructure to adapt access parameters to increase or decrease the likelihood of successful access. This allows the infrastructure to tune access parameters to particular mobile station information and it also allows the infrastructure to provide better resource management for both traffic channel assignments and access channel usage.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit of U.S. Provisional application No.60/258,620, filed Dec. 22, 2000, the content of which is incorporatedherein by reference in its entirety.

TECHNICAL FIELD

This invention relates to wireless communication systems, and moreparticularly to enhanced handoff control for wireless communicationsystems.

BACKGROUND

Cellular telephones may operate under a variety of standards includingthe code division multiple access (CDMA) cellular telephonecommunication system for which a 2^(nd) generation system is describedin TIA/EIA, IS-95, Mobile station-Base Station Compatibility Standardfor Dual-Mode Wideband Spread Spectrum Cellular System, published July1993 and a 3^(rd) generation system is described in TIA/EIA, IS-2000-AVolumes 1 through 6. CDMA is a technique for spread-spectrummultiple-access digital communications that creates channels through theuse of unique code sequences. In CDMA systems, signals can be and arereceived in the presence of high levels of interference. The practicallimit of signal reception depends on the channel conditions, but CDMAreception in the system described in the aforementioned IS-95 Standardcan take place in the presence of interference that is 18 dB larger thanthe signal for a static channel. Typically, the system operates with alower level of interference and dynamic channel conditions.

A mobile station utilizing one of the CDMA standards utilizes a set ofreverse channels to transmit data to the infrastructure and a set offorward channels to receive data from the infrastructure. Reversechannels include but are not limited to an Access Channel and one ormore Traffic Channels. The Access Channel is used by mobile stations forcommunicating usually short messaging signals to a specific basestation, where such signals include but are not limited to calloriginations, responses to infrastructure pages and systemregistrations. The various Access Channel messages are comprised of amessage body, a message length indicator and a cyclic redundancy check(CRC). Access Channel messages are contained in a data structure calledan Access Probe. An Access Probe comprises a preamble and an AccessChannel message. Access Probes are sent in sequences containing the samemessage until an acknowledgement to the message is received. A mobilestation will usually increase the power of each successive Access Probeuntil it receives an acknowledgment to the message or the accessparameters affecting transmit power are modified by the base station.The entire process of sending one Access Channel message and receiving(or failing to receive) an acknowledgment is known as an Access Attempt.

A typical mobile-originated connection setup scenario involves the useof multiple signaling messages on multiple channels. The mobile stationdetects input from the user, for example through keypad or voicedetection. The mobile station then initiates an Access Attempt bytransmitting an origination message encapsulated in a sequence of AccessProbes to a base station. The mobile station will continue transmittingAccess Probes containing the same origination message until it receivesan acknowledgement on the Forward Paging Channel from the base stationthat the Access Probe was transmitted to. When the base station receivesone of the Access Probes, and resources are available, it responds bysetting up a Forward Traffic Channel (defined by an orthogonal code suchas a Walsh Code, or a Quasi-Orthogonal Function), transmitting nulltraffic data on the traffic channel and transmitting a channelassignment message (including the acknowledgement) on the PagingChannel. However, if resources are not readily available, the basestation will transmit the acknowledgement along with Access Parameterinstructions to the mobile station on the Paging Channel. Accessparameter instructions can include, but are not limited to, changes inpersistence parameters, access probe power parameters, acknowledgementtimeout parameters, number of access probes per sequence or other wellknown access parameters. The mobile station will continue its AccessAttempt, as modified by the Access Parameter instructions received fromthe base station, until a connection is established.

The connection scenario described above can require many messages and,hence, can consume a large amount of network capacity. Therefore, anyway of consolidating this process, thereby conserving capacity, would bewelcomed by network operators and be appreciated by users due to fastconnection setup.

As discussed above, connection setup can be a process involving multiplereconnection attempts by the mobile station utilizing several AccessProbe sequences. It can also involve base station adaptation of AccessParameters, especially when network resources are limited. An AccessProbe containing an origination message generally contains a preambleand the origination message which contains information regarding whattype of connection is being requesting, the capabilities of therequesting mobile station and other overhead parameters. The basestation must manage the access channel parameters and traffic channelassignments based on a very limited knowledge of a particular mobilestation state. This invention provides a way for a base station tointelligently adapt access parameters and manage channel assignmentsbased on individual mobile station information.

SUMMARY

The invention consists of a method allowing a wireless infrastructure toadapt mobile station Access Parameters and manage limited channelresources based on detailed reconnection information obtained fromindividual mobile stations.

The invention involves a mobile station transmitting particularreconnection attempt status information, such as the number of attemptsso far and the reason(s) for the reconnections to the wirelessinfrastructure. A base station, or other infrastructure component, usesthis information along with the aggregate statistics of other mobilestations to determine if a particular variation in access parameters can(or has in the past) increase or decrease the possibility of successfulaccess. This allows the wireless infrastructure to use these statisticalresults, or predefined instructions and parameter values, to tune theaccess parameters based on a particular mobile station's stateinformation. It also allows the wireless infrastructure to providebetter resource management for both traffic channel assignments andaccess channel usage.

DESCRIPTION OF DRAWINGS

These and other features and advantages of the invention will becomemore apparent upon reading the following detailed description and uponreference to the accompanying drawings.

FIG. 1 illustrates the components of an exemplary wireless communicationsystem used by one embodiment of the present invention.

FIG. 2 is a block diagram showing features of a mobile station accordingto one embodiment of the invention.

FIG. 3 illustrates a process for tuning access parameters according toone embodiment of the present invention.

FIG. 4 illustrates an example of a connection/reconnection processaccording to one embodiment of the present invention.

DETAILED DESCRIPTION

FIG. 1 illustrates components of an exemplary wireless communicationsystem 100. A mobile switching center 102 communicates with basestations 104 a-104 k (only one connection shown). The base stations 104a-104 k (generally 104) broadcasts data to and receives data from mobilestations 106 within cells 108 a-108 k (generally 108). The cell 108,corresponding to a geographic region, is served by a base station.Practically, said geographic regions often overlap to a limited extent.

A mobile station 106 is capable of receiving data from and transmittingdata to a base station 104. In one embodiment, the mobile station 106receives and transmits data according to the Code Division MultipleAccess (CDMA) standard. A set of standards that define a version of CDMAthat is particularly suitable for use with the invention include IS-95,IS-95A, and IS-95B, Mobile Station-Base Station Compatibility Standardfor Dual-Mode Spread Spectrum Systems; TIA/EIA/IS-2000-2, Physical LayerStandard for cdma2000 Spread Spectrum Systems; and TIA/EIA/IS-2000-5Upper Layer (Layer 3) Signaling Standard for cdma2000 Spread SpectrumSystems, all of which are herein incorporated by reference in theirentirety. CDMA is a communication standard permitting mobile users ofwireless communication devices to exchange data over a telephone systemwherein radio signals carry data to and from the wireless devices.

Under the CDMA standard, additional cells 108 a, 108 c, 108 d, and 108 eadjacent to the cell 108 b permit mobile stations 106 to cross cellboundaries without interrupting communications. This is so because basestations 104 a, 104 c, 104 d, and 104 e in adjacent cells assume thetask of transmitting and receiving data for the mobile stations 106. Themobile switching center 102 coordinates all communication to and frommobile stations 106 in a multi-cell region. Thus, the mobile switchingcenter 102 may communicate with many base stations 104.

Mobile stations 106 may move about freely within the cell 108 whilecommunicating either voice or data. Mobile stations 106 not in activecommunication with other telephone system users may, nevertheless, scanbase station 104 transmissions in the cell 108 to detect any telephonecalls or paging messages directed to the mobile station 106. Mobilestations 106 can also initiate a connection by transmitting anorigination message to a particular base station sector 104 that it isscanning.

One example of such a mobile station 106 is a cellular telephone used bya pedestrian who, wishing to establish a connection, powers on thecellular telephone while walking in the cell 108. The cellular telephonescans certain frequencies (frequencies known to be used by CDMA) tosynchronize communication with the base station 104. The cellulartelephone then registers with the mobile switching center 102 to makeitself known as an active user within the CDMA network.

When originating a connection the cellular telephone detects input fromthe user, for example through keypad or voice detection. A connection asreferred to herein includes, but is not limited to, voice, multimediavideo or audio streaming, packet switched data and circuit switched dataconnections, short message sequences or data bursts, and paging. Thecellular telephone then initiates an Access Attempt by transmitting anorigination message encapsulated in a sequence of Access Probes to basestation 104. The cellular telephone will continue transmitting AccessProbes containing the same origination message until it receives anacknowledgement on the Forward Paging Channel from the base station 104that the Access Probe was transmitted to. When the base station 104receives one of the Access Probes, and resources are available, itresponds by setting up a Forward Traffic Channel (defined by anorthogonal code such as a Walsh Code, or a Quasi-Orthogonal Function),transmitting null traffic data on the traffic channel and transmitting achannel assignment message (including the acknowledgement) on the PagingChannel. However, if resources are not readily available, the basestation 104 will transmit the acknowledgement along with AccessParameter instructions to the cellular telephone on the Paging Channel.Access parameter instructions can include, but are not limited to,changes in persistence parameters, access probe power parameters,acknowledgement timeout parameters, number of access probes per sequenceor other well known access parameters. The cellular telephone willcontinue its Access Attempt, as modified by the Access Parameterinstructions received from the base station 104, until a connection isestablished.

FIG. 2 shows a block diagram of the mobile station 106 and theprocessing that occurs in that mobile station 106. A program stored in amemory 205 drives the processor 200. Access parameters that control theactions taken by the mobile station with regard to use of the accesschannel may be stored in memory 210.

The present invention involves each mobile station or a subset of allmobile stations served by a base station (or a sector of a base station)transmitting reconnection information to the base station whileattempting to establish mobile originated connections. The reconnectioninformation includes, but is not limited to, the reason for thereconnection, the number of reconnection attempts transmitted, theAccess Probe power level and the Access Probe Number. The reasons forthe reconnection include, but are not limited to, no response from thebase station (access failure), and refusal of channel assignment fromthe base station (access retry). In one embodiment of the presentinvention, if there is an access failure, then the reconnectioninformation is input to the access parameter tuning algorithm. Inanother embodiment, if there is an access retry rejection, then thereconnection information goes into the resource management process thatprioritizes re-connections/connections. In one embodiment, the number ofreconnection attempts include only the number that have occurred(including the current one) for the same reconnect reason as the currentone. In another embodiment, the number includes only the consecutivereconnection attempts occurring for the same reason as the current one.The later embodiment could be useful to include in the aggregatestatistics since only repetitive problems are accented with highnumbers.

The reconnection information described above can be collected by theinfrastructure and used to adapt the access parameters to allow forfaster connection setup. This adaptation can be performed on the baseaccess parameters that are transmitted to all mobile stations served inthe area of interest or can be access parameters that affect only onemobile station, or a subset of mobile stations can be individuallytuned. FIG. 3 illustrates a process 300 for tuning access parametersaccording to one embodiment of the present invention. The process firstinitializes the threshold and algorithm parameters 305. In oneembodiment the thresholds are upper and lower hysteresis levels ofaccess success. In another embodiment the hysteresis levels are lowerand upper bounds on distribution of number of retries. The algorithmparameters will depend on the specific indicator algorithm used and anexample embodiment will be described below. The process 300 will bedescribed without regard to the specific indicator algorithm. FIG. 3shows an embodiment where the algorithm exhibits an inverse correlationto success rate (i.e. as success rate increases, the indicator algorithmdecreases and vice-versa).

After the initialization 305, the process checks the current indicatoragainst the upper and lower hysteresis levels to determine if anincrease or decrease in access parameter aggressiveness is needed 310.If the indicator is less than the lower hysteresis level, then adecrease is necessary and the process proceeds to 315. If the indicatoris greater than the upper hysteresis level, then an increase isnecessary and the process proceeds to 320. If neither hysteresis levelis violated (i.e. the indicator is between the lower and upperhysteresis levels), the process may optionally proceed to 335 (path notshown in FIG. 3) to collect statistics on current mobile stationinformation. In 315 and 320, the process compares the most recentindicator value to the previous indicator value (or a filtered value ofpast indicator values). If this is the first time attempting to decrease315 or increase 320 aggressiveness, the comparisons 315 and 320 areskipped and the access parameter aggressiveness is decreased 325 orincreased 330 respectively. If the comparison 315 shows that the currentindicator is greater than the past indicator value (but a decrease isstill needed since the process already proceeded to 315) then the accessparameter aggressiveness is decreased further. If the comparison 315shows that the current indicator is less than the past indicator value(indicating that the decreased aggressiveness parameters did not havethe desired effect) then the process proceeds to 330 where the parameteraggressiveness is increased (possibly by simply resetting them to thevalues prior to the last decrease). A similar procedure occurs in theincreased aggressiveness path of 320 and 330. After the AccessParameters are decreased 325 or increased 330, the process proceeds to335 where the most recent mobile stations reconnection informationstatistics are collected. After collecting statistics, the accesssuccess indicator values are computed for mobile stations 340. Theprocess then proceeds to 310 where the just computed access successindicators are compared to the threshold levels and the process repeats.An example of an indicator that has an inverse correlation with accesssuccess is the percentage of retries that take more attempts than isconsidered ideal.

The access success indicator discussed above can take many forms. Ingeneral the indicator must be chosen so that it has a strong correlationwith the access success rate. An example embodiment of an indicator witha strong correlation to access success rate follows.

In one embodiment, the mobile station may keep track of how many retrieshave occurred for each re-connection attempt. This information may bestored locally in a database and an average may be computed. The mobilestation may categorize the data according to number of retries. Considerdenoting the set of all reconnections received by a base station andlabeled as access failures because there was no response received at themobile as the set R, and denoting the set of attempts that were the j'thretry attempt of a connection as the set R_(j). The ratio ofreconnections that required j reconnection attempts can be computed asthe size of the set R_(j) minus the size of the set R_((j+1)) (i.e. thenumber of j'th retries less the number of (j+1)'th retries) over thetotal number of reconnections. Denoting set size, or cardinality, byvertical bars, the ratio r can be written asr_(j)=(|R_(j)|−|R_(j+1)|)/R₀. In one embodiment, the system may examinethe distribution of r_(j) across the parameter j. The system may betuned, or tune itself such that r_(j) falls off after a threshold valuek. For example, if k=3, then no more than 3 retries are generallyrequired to reconnect and r_(k+1) is much less than r_(k). The systemmay tune itself using an algorithm that examines the parameter r_(k) andr_(k+1) and adjusting access or reconnect parameters to tune thedistribution of r. Alternatively, in another embodiment, the system maytune itself by examining the parameter r₁ (i.e. r at a specific point l)as time varies and as the system adapts. For example, the system mayattempt an adaptation step of increasing or decreasing theaggressiveness of access parameters and then examine if the statistic r₁has adjusted in the desired direction. Note that 1 may be set equal tok, k+1 or any other threshold or number of retries of interest. Theindicator in FIG. 3 may be considered, for example, as r_(k)(t), where tis the current time. Alternatively, the indicator in FIG. 3 may beconsidered, for example, as r(t) where t=k or t=k+1. In this latterexample, the decision blocks 315 and 320 are determining if the desiredrelationship between number of retries, i.e. fall-off after k retries,exists or if adaptation is required.

Access parameter aggressiveness may be increased by increasing theinitial power level, power step size, number of access probes, number ofprobe sequences, or any other access related parameter that may increasethe chance of a base station receiving the mobile station accesstransmission sooner. Increasing access parameter aggressiveness mayinvolve considering the tradeoff of interference implications due tohigher power transmissions. Ideally, the number of access transmissionsor duration of access transmissions should be minimized while alsominimizing the time until the power level reaches and does not overlyexceed a level receivable by the base station. The purpose of increasingaccess parameter aggressiveness is to improve the chances that a mobilestation transmission is received as soon as possible by a base stationwithout excess interference in the reverse link.

Decreasing access parameter aggressiveness may include lowering initialpower level, power step size, number of access probes, number of probesequences, or any other access related parameter that may decrease thechance of mobile transmissions that are unnecessarily long or strongwhile maintaining a satisfactory chance of a base station receiving themobile station access transmission within a satisfactory time period.The purpose of decreasing access parameter aggressiveness is to reducethe chance of unnecessary interference through unnecessarily strong,long, or number of access transmissions.

The access probing method is designed to start at a relatively low powerand increase power of transmissions until the base station receives themobile station transmission. The access parameters may be initiallyconfigured by a network engineer to correspond to average signalenvironment conditions within a sector or cell. A single set of accessparameter values may not be ideal for all conditions. The idealparameter values may vary with time, location, mobile station, and otherenvironmental or user characteristics. Adaptation of access parametersmay take into account variation in the ideal values by using ahysteresis method. In such a method threshold levels may be establishedabout the desired access performance so that the parameters are onlytuned if the performance is worse or better than the respectivehysteresis bounds.

The infrastructure may also use the access retry information transmittedby the mobile for resource management/planning (as opposed to the accessfailure information that was used in the access parameter tuning processabove). The access retry information corresponds to those reconnectionattempts that are made due to refusal by the infrastructure to allocatea traffic channel. This may be particularly useful for packet dataconnections. The base station may respond differently to each mobiledepending on how many access retry attempts the mobile has made so far.For example, the base station could ask the mobile to wait longer beforetrying to reconnect next time. The base may use statistics about howmany pending connections there are and how long they have been pendingto release and re-assign resources.

In one embodiment, the infrastructure may keep track of pendingconnections that were requested to reattempt in the future. Theinfrastructure may thereby optimally re-schedule future new connectionrequests. The infrastructure may also maintain a database of connectiondurations correlated with the type of connection, user or othercharacteristic and use this information to predict the end ofconnections. This information can further be used as input fordetermining how long to ask a terminal requesting a new connection orreconnection to wait until retrying.

FIG. 4 shows an example of using both the mobile station reasons forreconnection (either access failures or access retries) and the numberof failed retry attempts of that type to control when the mobileretries. A mobile station 106 is attempting to set up a connection to abase station 104. The base station's resources (e.g. traffic channels)at the start of the access attempt are all in use 400. The mobilestation transmits an access probe containing an origination message,which includes, among other data, a reconnection attempt 405. Thereconnection attempt contains the reason for the reconnection and thenumber of times that this type of failure has occurred. Since 405 is thefirst attempt to set up a connection, the reason is N/A and the numberof times is zero. After waiting for an acknowledgement from base station104 for the required amount of time, the mobile station 106 transmits asecond reconnection attempt 410 containing a “No Response” reasonindicating an access failure and a number one indicating that this isthe first reconnection due to an access failure. After waiting for anacknowledgement from the base station 104, the mobile station transmitsa third reconnection attempt 415 containing a “No Response” reason and anumber 2 indicating that this is the second reconnection attempt of the“No Response” type. Since no resources are available, the base station,after successfully receiving attempt 415, transmits an originationresponse message 420 containing an indicator to the mobile station 105that it should retry the reconnection in 64 seconds. The base stationcan use the reconnection information contained in 415 to adapt accessparameters in the future as presented for the access parameter tuningalgorithm. One resource temporarily becomes available 425 before themobile station's 64 second delay period elapses. The resources are onceagain all in use at 430. After waiting the instructed 64 seconds, themobile station transmits a reconnection attempt 435 containing thereason “Retry” and the number 1 indicating that this is the firstreconnection attempt because of an access retry. Since all resources arein use, the base station, after successfully receiving message 435,transmits an origination response message 440 containing instructionsfor the mobile station to wait 256 seconds before attempting areconnection. The base station can use the reconnection informationcontained in 435 for future resource management and planning. Before the256 second timer expires, a resource becomes available 445. The mobilestation transmits a reconnection attempt containing the reason “Retry”and the number 2 indicating that this is the second reconnection attemptresulting from an access retry. After successfully receiving message450, the base station 104 transmits an origination response messagecontaining a channel assignment that sets up a traffic channel formobile station 106. The base station 104 can also use the reconnectioninformation in 450 for use in future resource management and planningstrategies. Thus, the mobile station 106 concludes a successful accessattempt.

Note also that embodiments of the present invention can be generalizedto communications protocols other than CDMA. Systems incorporating TDMAor FDMA or combinations of both can easily adapt the connection accessmethods to include the present invention. Note also, that systems otherthan cellular telephone systems, such as adhoc wireless networks,wireless LAN and WAN networks could also utilize the present invention.

Numerous variations and modifications of the invention will becomereadily apparent to those skilled in the art. Accordingly, the inventionmay be embodied in other specific forms without departing from itsspirit or essential characteristics.

1-31. (canceled)
 32. A wireless communication system comprising: amobile station which transmits a plurality of reconnection attemptmessages, each message containing a parameter identifying a reason for apreviously failed reconnection attempt and a parameter indicating anumber of times that the reason has occurred; a base station whichattempts to receive the plurality of reconnection attempt messages and,if the attempt to receive succeeds, wherein the base station stores theparameter identifying the reason for the previously failed reconnectionattempt and the parameter indicating the number of times that the reasonhas occurred.
 33. The wireless communication system of claim 32, whereinthe reason for the previously failed reconnection attempt is one of thegroup consisting of an access failure, a lack of resources, anacknowledgment failure, a connection denial, and lack of channelassignment.
 34. The wireless communication system of claim 32, whereinthe base station adapts system access parameters using said parameters.35. The wireless communication system of claim 32, wherein the basestation controls resources using said stored parameters.
 36. Thewireless communication system of claim 35, wherein the resources areselected from the group consisting of packet data resources, circuitswitched resources, common channels, dedicated channels, forwardchannels, reverse channels, shared channels, and voice channels.
 37. Thewireless communication system of claim 32, wherein the base stationdetermines a time to re-attempt connection using said stored parameters.38. The wireless communication system of claim 32, wherein the parameterindicating a number of times that the reason has occurred identifies anumber of consecutive reconnection attempts for the same reason.
 39. Thewireless communication system of claim 32, wherein the parameterindicating a number of times that the reason has occurred identifies anumber of reconnection attempts for the same service option selection.40. The wireless communication system of claim 39, wherein the number ofreconnection attempts for the same service option selection is for acurrent connection only.
 41. The wireless communication system of claim39, wherein the number of reconnection attempts for the same serviceoption selection is the number of consecutive reconnection attempts. 42.The wireless communication system of claim 32, wherein the parameterindicating a number of times that the reason has occurred identifies anumber of silent retries.
 43. The wireless communication system of claim42, wherein the number of silent retries is the number of consecutivesilent retries.